Silicon-based thin films from n-alkyl substituted perhydridocyclotrisilazanes

ABSTRACT

Low to moderate temperature vapor deposition processes are provided for the deposition of silicon-based thin films, such as silicon nitride films, silicon carbonitride films, silicon oxide films, and silicon films. The processes includes in a single cycle, heating a substrate to a predetermined temperature; providing a precursor containing an N-alkyl substituted perhydridocyclotrisilazane in the vapor phase to a reaction zone containing the substrate, forming a monolayer of the precursor by adsorption to the substrate surface, and exposing the adsorbed monolayer on the substrate in the reaction zone to a remote or direct soft plasma of a co-reactant. The adsorbed precursor monolayer reacts with the soft plasma and undergoes conversion to a discrete atomic or molecular layer of a silicon-based thin film via dissociation and/or decomposition due to or enabled by a substrate surface-induced process. The cycle is then repeated to form a silicon-based thin film of a desired thickness.

CROSS REFERENCE TO RELATED APPLICATION

This application claims priority to U.S. Provisional Patent Application No. 60/030,684, filed May 27, 2020, the disclosure of which is herein incorporated by reference.

BACKGROUND OF THE INVENTION

Research, development, and manufacturing interests in Si-based thin films, such as (SiN_(x)) and silicon oxide (SiO₂), are at an unprecedented intensity, driven not only by the need to extend its historical applicability in the ever evolving integrated circuitry (IC) and solar cell industries, but also by its potential use in a myriad of new applications. The latter include, for instance, host matrices for Si nanocrystals (Si—NCs) and quantum dots (QDs) for photoluminescence applications, waveguides in nonlinear frequency combs for sensors and photonic devices for telecommunications, tunable luminescent films for Si-based light emitting diodes (LEDs) in Si based monolithic optoelectronic integration, passivation/encapsulation nanostructures at the interface with gallium arsenide (GaAs) for compound semiconductor devices, and base platform for integration with biological materials for biochemistry and medical applications.

The tremendous appeal of Si-based thin films is propelled by its highly attractive mix of physical, chemical, mechanical, electrical, and optoelectronic properties, which make it one of the most commonly used materials across a diversified array of industries. Many of these industries share the same evolutionary drivers in terms of migration towards the incorporation of heterodevice structures with smaller feature sizes using thermally and/or chemically sensitive substrates. As a result, R&D activities have focused on the development and optimization of low-temperature deposition processes, such as direct and remote plasma-enhanced chemical vapor deposition (PE-CVD), laser-assisted CVD, mirror-plasma enhanced chemical vapor deposition (MPECVD), multiple-holes hollow-cathode radio-frequency (RF) PECVD, and direct, remote, and glow-discharge plasma-enhanced atomic layer deposition.

Despite these extensive R&D efforts, significant challenges must be overcome to enable the extendibility of Si-based thin films to heterodevice applications. For one, the lion share of PE-CVD and PE-ALD processes rely on the use of silane (SiH₄) and silane-type precursors. The inherent issues associated with the use of such chemistries are well documented and include their pyrophoric nature, increased thermal budget, and the incorporation of high levels of hydrogen. In addition, PE-ALD processes using silane-type silicon sources suffer from substrate surface adsorption and nucleation problems, thus requiring substrate surface pre-treatment which adds complexity and cost. Furthermore, the resulting films consist quite frequently of varying concentrations of silicon, oxygen, and nitrogen, with the inclusion of significant levels of contaminants, and/or the presence of Si to N and Si to O compositional gradients between the interfacial, bulk, and surface regions of the films.

For these reasons, it is desirable to provide a thin film deposition technique that overcomes the above-discussed drawbacks of conventional deposition techniques by depositing high-quality Si-based thin films, such as (SiN_(x)) and silicon oxide (SiO₂), as well as their alloys, such as SiC_(x)N_(y), at low temperature, while minimizing the number and complexity of substrate surface pre-treatment steps and thereby maximizing process efficiency and productivity.

BRIEF SUMMARY OF THE INVENTION

In one embodiment, the present disclosure relates to a method for deposition of a silicon nitride thin film onto a substrate in a reaction zone of a deposition chamber, the method comprising, in a single cycle: heating a substrate to a temperature of about 200° C. to about 650° C.; maintaining the substrate at about 200° C. to about 650° C.; providing a precursor comprising a N-alkyl substituted perhydridocyclotrisilazane in the vapor phase with a carrier gas and/or under vacuum to the reaction zone containing the substrate; forming a monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface; and exposing the adsorbed monolayer on the substrate in the reaction zone to a remote or direct soft plasma of a nitrogen-containing reactant; wherein the adsorbed N-alkyl substituted perhydridocyclotrisilazane monolayer reacts with the soft plasma and undergoes conversion to a discrete atomic or molecular layer of a silicon nitride thin film via dissociation and/or decomposition due to or enabled by a substrate surface-induced process; and wherein byproducts of the conversion are removed from the reaction zone via a purge step with an inert gas and/or the vacuum.

In a second embodiment, a method for deposition of a silicon oxide thin film onto a substrate in a reaction zone of a deposition chamber comprises, in a single cycle: heating a substrate to a temperature of about 200° C. to about 650° C.; maintaining the substrate at about 200° C. to about 650° C.; providing a precursor comprising a N-alkyl substituted perhydridocyclotrisilazane in the vapor phase with a carrier gas and/or under vacuum to the reaction zone containing the substrate; forming a monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface; and exposing the adsorbed monolayer on the substrate in the reaction zone to a remote or direct soft plasma of an oxygen-containing reactant; wherein the adsorbed N-alkyl substituted perhydridocyclotrisilazane monolayer reacts with the soft plasma and undergoes conversion to a discrete atomic or molecular layer of a silicon oxide thin film via dissociation and/or decomposition due to or enabled by a substrate surface-induced process; and wherein byproducts of the conversion are removed from the reaction zone by an inert gas through a purge step and/or the vacuum.

In a further embodiment, the disclosure provides a method for deposition of a silicon carbonitride thin film onto a substrate in a reaction zone of a deposition chamber, the method comprising, in a single cycle: heating a substrate to a temperature of room temperature to about 200° C.; maintaining the substrate at room temperature to about 2000° C.; providing a precursor comprising a N-alkyl substituted perhydridocyclotrisilazane in the vapor phase with a carrier gas and/or under vacuum to the reaction zone containing the substrate; forming a monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface; and exposing the adsorbed monolayer on the substrate in the reaction zone to a remote or direct soft plasma of a nitrogen-containing reactant; wherein the adsorbed N-alkyl substituted perhydridocyclotrisilazane monolayer reacts with the soft plasma and undergoes conversion to a discrete atomic or molecular layer of a silicon carbonitride thin film via dissociation and/or decomposition due to or enabled by a substrate surface-induced process; and wherein byproducts of the conversion are removed from the reaction zone by an inert gas through a purge step and/or the vacuum.

In another embodiment, the disclosure provides method for deposition of a silicon thin film onto a substrate in a reaction zone of a deposition chamber, the method comprising, in a single cycle: heating a substrate to a temperature of about 200° C. to about 650° C.; maintaining the substrate at about 200° C. to about 650° C.; providing a precursor comprising a N-alkyl substituted perhydridocyclotrisilazane in the vapor phase with a carrier gas and/or under vacuum to the reaction zone containing the substrate; forming a monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface, and exposing the adsorbed monolayer on the substrate in the reaction zone to a remote or direct soft plasma of a hydrogen-containing reactant; wherein the adsorbed N-alkyl substituted perhydridocyclotrisilazane monolayer reacts with the soft plasma and undergoes conversion to a discrete atomic or molecular layer of a silicon thin film via dissociation and/or decomposition due to or enabled by a substrate surface-induced process; and wherein byproducts of the conversion are removed from the reaction zone by an inert gas through a purge step and/or the vacuum.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

The following detailed description of preferred embodiments of the present invention will be better understood when read in conjunction with the appended drawing. For the purposes of illustrating the invention, there is shown in the drawing an embodiment which is presently preferred. It is understood, however, that the invention is not limited to the precise arrangements and instrumentalities shown. In the drawings:

FIG. 1 is a graph of TICZ experimental vapor pressure data and Antoine Equation's fit over the range of 0.14 to 760 torr.

FIG. 2 is an optimized SiN_(x) process window schematic for various substrate temperatures ranging from 50 to 350° C.

FIG. 3 is a graph of in-situ, real-time, ellipsometry measurements of film thickness versus deposition time for substrate temperature of 200° C. for TICZ exposure times of 0.4 sec, 1.0 sec, 2.0 secs, 3.0 secs, and 5.0 secs.

FIG. 4 is a graph of in-situ, real-time, ellipsometry measurements of film thickness versus deposition time for substrate temperatures of 150, 175, 200, 225, 300, and 350° C.

FIG. 5 is a graph of in-situ, real-time, ellipsometry measurements of film thickness versus deposition time for the first minute of SiN_(x) processing.

FIG. 6 is an XPS profile of Zn, Si, N, C, and O concentrations versus penetration depth in SiN_(x) films deposited at 200° C.

FIG. 7 is an XPS profile of Zn, Si, N, C, and O concentrations versus penetration depth in SiN_(x) films deposited at 300° C.

FIG. 8 depicts high-resolution XPS spectra for Si2p, N1s, C1s, and O1s binding energies versus penetration depth in SiN_(x) films deposited at 200° C.

FIG. 9 depicts high-resolution XPS spectra for Si2p, N1s, C1s, and O1s binding energies versus penetration depth in SiN_(x) films deposited at 300° C.

FIG. 10 is an XPS depth profile of Zn, Si, N, C, and O concentrations for SiC_(x)N_(y) films deposited at 50° C.

FIG. 11 is an XPS depth profile of Zn, Si, N, C, and O concentrations for SiC_(x)N_(y) films deposited at 150° C.

FIG. 12 depicts high-resolution XPS core level spectra for Si 2p, N 1s, C 1s, and O 1s binding energies versus penetration depth in SiC_(x)N_(y) films deposited at 50° C.

FIG. 13 depicts high-resolution XPS core level spectra for Si2p, N1s, C1s, and O1s binding energies versus penetration depth in SiC_(x)N_(y) films deposited at 150° C.

FIG. 14 is a graph of in-situ, real-time, angle-resolved ellipsometry measurements of SiC_(x)N_(y) film thickness versus deposition time for a substrate temperature of 150° C. and TICZ pulse times of 0.1 second, 0.2 second, 0.4 second, and 0.8 second.

FIG. 15 is a graph of in-situ, real-time, angle-resolved ellipsometry measurements of SiC_(x)N_(y) film thickness versus deposition time for substrate temperatures of 30, 60, 90, 120, 150, and 170° C.

DETAILED DESCRIPTION OF THE INVENTION

Aspects of the disclosure relate to low to moderate temperature vapor deposition processes for the deposition of Si-based thin films onto substrates in the reaction zone of a deposition chamber. The processes include, in a single cycle, heating a substrate to a desired temperature and maintaining the substrate at this temperature, providing a precursor comprising an N-alkyl substituted perhydridocyclotrisilazane in the vapor phase with a carrier gas and/or under vacuum to a reaction zone containing the substrate, forming a monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption on the substrate surface, optionally removing unreacted perhydridocyclotrisilazane and byproducts thereof from the reaction zone using an inert gas through a purge step and/or the vacuum, and exposing the adsorbed monolayer on the substrate in the reaction zone to a remote or direct soft plasma of another chemical species or co-reactant, wherein the adsorbed N-alkyl substituted perhydridocyclotrisilazane monolayer reacts with the soft plasma and undergoes conversion to a discrete atomic or molecular layer of a Si-based thin film via dissociation and/or decomposition due to or enabled by a substrate surface-induced process, in which byproducts of the conversion are removed from the reaction zone by an inert gas via a purge step and/or the vacuum. The single cycle is then repeated as many times as desired to form a Si-based thin film of a desired or predetermined thickness. As described in detail below, the appropriate substrate temperature and the components of the soft plasma are determined by the desired chemical composition of the silicon-based thin film, such as silicon nitride, silicon carbonitride, silicon oxide, or silicon.

The term “thin film” is well understood in the art, and may include films ranging in thickness from a few nanometers to a few microns. As explained above, such film thickness is controlled by the number of cycles which are performed.

In some embodiments, the conversion of the adsorbed monolayer to a discrete atomic or molecular layer may be aided or enabled by energy transfer provided from an energy source, such as a heated substrate. For example, surface-induced processes, such as energy transfer (thermal exposure) from the substrate, remote or direct plasma application, oxidation, and/or reduction may be used to initiate or facilitate conversion of the adsorbed monolayer to the final deposited film.

The term “soft plasma” refers to plasma-induced processes which impart minimum energy onto a subject film or substrate so as to result in very little or no mechanical, chemical, physical, or electrical damage to the film and substrate. Similarly, soft plasma refers to plasma-induced processes which impart energy onto the subject molecule which is lower than the threshold for breakage, fragmentation, or decomposition of the subject molecule. Instead, a soft plasma is designed to impart sufficient activation energy to the precursor to enable its controlled decomposition in combination with an additional source of thermal energy, preferably on a substrate surface.

The processes described herein employ as Si source precursors the class of N-alkyl substituted perhydridocyclotrisilazanes. Unlike perhydridocyclic silazanes with methyl groups on the N atoms, this class of silazanes contains alkyl radicals with at least two carbon atoms on each N atom, providing a mechanism for low to moderate temperature SiN_(x) deposition by elimination of the alkyl substitutions. In contrast, the simple methyl groups in the methyl-substituted perhydridocyclic silazanes require higher temperatures for film formation and incorporate significantly higher carbon concentration into the resulting films. This is presumably due to the lack of a low-energy elimination mechanism for these methyl groups.

The favorable chemical structure and bonding configuration of the N-alkyl substituted perhydridocyclotrisilazanes have been engineered to enable the clean removal of the alkyl groups at low to moderate temperature to yield pure Si-based thin films. Furthermore, the presence of H atoms on the Si atoms minimizes the steric hindrance and provides the precursor molecule higher accessibility to reactive substrate surface sites, whether those sites are H-terminated (such as Si) or HO-terminated (such as SiO₂). In other words, the precursor adsorption to the substrate surface and possible partial decomposition through breakage of some of its ligands is immediate upon contact with the substrate. This feature has important implications, as film nucleation and growth can occur instantaneously in the first cycle without the existence of an incubation period, in contrast to what is reported in the prior art, thus eliminating the need for substrate surface pre-treatments that result in additional complexity and added cost of ownership.

The film-forming processes according to the disclosure are plasma-activated, not plasma-enhanced or plasma-assisted. In a plasma activated process, the precursor exposure step is carried out thermally without the involvement of a plasma, while the co-reactant (such as, for example, NH₃, N₂, N₂+H₂, hydrazine, oxygen, ozone, water, or H₂) is introduced in a direct or remote soft plasma. As such, the precursor adsorption step is activated by thermal and chemical energy from the substrate and not from a plasma, which enables the precursor (or a partial precursor species due to the possible elimination of some of the precursor ligands or attached radicals and groups upon engagement with the substrate) to adsorb physically or chemically in a conformal fashion to the various substrate surface topographies, including, for example, high aspect ratio via and trench structures. As a result, the subsequent remote or direct co-reactant plasma will lead to the formation of the desired film conformally with equal thickness across the entire substrate surface, including in highly aggressive device geometries.

The processes according to the disclosure are performed at a substrate temperature that leads to partial or complete decomposition of the pulsed precursor upon engagement with the substrate during every exposure cycle, as opposed to being limited to a mere physisorption or chemisorption reaction of the complete precursor. A co-reactant is subsequently introduced to complete the decomposition reaction and/or remove the reaction byproducts to ensure a clean film. As such, the process requires lower thermal, chemical, or plasma-energy to grow the target film since the precursor has already partially decomposed upon reaching the substrate surface.

The decomposition of the precursor in the methods according to the disclosure is induced by three processes working in tandem: precursor adsorption to the substrate with partial removal of some ligands, thermal energy from the substrate, and soft plasma activation.

Appropriate substrates include, without limitation, those formed of a material selected from the group consisting of silicon, silicon oxide, copper, platinum, titanium, titanium nitride, tantalum and tantalum nitride.

The process described herein is equally applied to the reaction of the N-alkyl substituted perhydridocyclotrisilazanes with a nitrogen source such as, without limitation, a direct or remote NH₃, N₂, N₂+H₂, hydrazine, or methylamine soft plasma, to form silicon nitride (SiN_(x)); an oxygen source, such as, without limitation, a direct or remote ozone, water, or O₂ soft plasma, to form silicon oxide (SiO₂); and a reactive hydrogen source, such as a direct or remote H₂ soft plasma, to form pure Si. The process may also be applied to the formation of SiC_(x)N_(y) compound thin films through the decomposition of N-alkyl substituted perhydridocyclotrisilazanes via exposure to a direct or remote soft plasma of a nitrogen- or carbon-containing chemical species or co-reactants. The ratio of C to N (C/N) in the films is modulated by controlling the substrate temperature and duration of the co-reactant pulse.

Specifically, control of the substrate temperature in the reaction zone of the deposition chamber affects the chemical composition of the resulting silicon-containing thin film. Specifically, in light of the chemical structure and bonding configuration of the N-alkyl substituted perhydridocyclotrisilazanes, the energetics of the reaction between the soft plasma and the source precursor at higher, but moderate, substrate temperatures (such as about 200° C. to about 650° C., preferably about 200° C. to about 350° C.) leads to the formation of SiN films, whereas low substrate temperatures (room temperature to about 200° C., preferably about 30° C. to about 200° C.) lead to the formation of SiC_(x)N_(y) films consisting of a matrix of simple Si—C and Si—N bonds, with no C—N bonds. For the purposes of this disclosure, the term “room temperature” may be understood to refer to temperatures from about 20° C. to about 27° C. In both processes, a direct or remote soft plasma of a nitrogen-containing reactant, such as but not limited to NH₃, N₂, N₂+H₂, hydrazine, or methylamine, is exposed to the adsorbed monolayer on the substrate. A direct or remote soft plasma of a carbon-containing chemical species such as acetylene may also be employed to form the silicon carbonitride thin film. The adsorbed N-alkyl substituted perhydridocyclotrisilazane monolayer reacts with the soft plasma and undergoes conversion to a discrete atomic or molecular layer of a silicon carbonitride thin film via dissociation and/or decomposition due to or enabled by a substrate surface-induced process.

The processes according to the disclosure are distinctly different from plasma enhanced chemical vapor deposition (PE-CVD) since the formation of the film on the surface is not associated with vapor phase interactions of the precursor with plasma. While a purge step, i.e., a mechanism to remove non-adsorbed (unreacted) precursor and co-reactant, as well as byproducts from the vapor phase by vacuum or an inert gas flow is not required, such a step is preferred in some embodiments to eliminate the potential for undesirable vapor phase reactions. Such byproducts of the reaction of the parent precursor with the co-reactant and its subsequent decomposition include, for example, ligands and partial ligands from the parent molecule as well as partially decomposed precursor. Byproducts may also include partially decomposed co-reactant species and entities formed from precursor ligands and co-reactant species.

In one embodiment, aspects of the disclosure relate to the development and optimization of a plasma-activated process from one perhydridocyclotrisilazane, namely, 1,3,5-tri(isopropyl)cyclotrisilazane (TICZ, C₉H₂₇N₃Si₃), which contains three C atoms on each N in the form of a propyl group. The latter is eliminated at moderate temperatures in the form of the gaseous byproduct propylene, as shown in Scheme 1:

Using such a perhydridocyclotrisilazane, thin films of SiN_(x) (where 0<x<1.33) may be produced at moderate temperature. A process is accordingly provided for forming SiN_(x) thin films using an N-alkyl substituted perhydridocyclotrisilazane precursor and a nitrogen-containing soft plasma co-reactant at moderate temperature (substrate temperatures of about 200° C. to about 650° C., preferably about 200° C. to about 350° C.), and, in preferred embodiments, employing TICZ and soft remote ammonia (NH₃) plasma co-reactants. It may be understood that the ranges of substrate temperatures are inclusive of all temperatures within the range, so that temperatures of about 200° C. to about 650° C. include temperatures such as about 225° C., about 250° C., about 275° C., about 300° C., about 325° C., about 300° C., about 325° C., about 350° C., about 375° C., about 400° C., about 425° C., about 450° C., about 475° C., about 500° C., about 525° C., about 550° C., about 575° C., about 600° C., about ° C. 625, and about 650° C., and all temperatures in between.

This exemplary process for depositing such silicon nitride thins film onto a substrate in a reaction zone of a deposition chamber comprises, in a single cycle: heating a substrate to a temperature of about 200° C. to about 650° C., preferably about 200° C. to about 350° C.; maintaining the substrate at about 200° C. to about 650° C., preferably about 200° C. to about 350° C.; providing 1,3,5-tri(isopropyl)cyclotrisilazane in the vapor phase with a carrier gas and/or under vacuum to the reaction zone containing the substrate; forming a monolayer of the 1,3,5-tri(isopropyl)cyclotrisilazane by adsorption to the substrate surface; and exposing the adsorbed monolayer on the substrate in the reaction zone to a remote or direct soft plasma of a nitrogen-containing reactant; wherein the adsorbed 1,3,5-tri(isopropyl)cyclotrisilazane monolayer reacts with the soft plasma and undergoes conversion to a discrete atomic or molecular layer of a silicon nitride thin film via dissociation and/or decomposition due to or enabled by a substrate surface-induced process; and wherein byproducts of the conversion are removed from the reaction zone via a purge step with an inert gas and/or the vacuum. The cycle is then repeated as many times as desired to form a SiN_(x) thin film of a desired or predetermined thickness. The nitrogen-containing chemical species or co-reactant may be, for example and without limitation, NH₃, N₂, a mixture of N₂ and H₂, methylamine, and/or hydrazine; NH₃ is presently preferred.

In some embodiments, after forming the monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface, unreacted N-alkyl substituted perhydridocyclotrisilazane and byproducts thereof are removed from the reaction zone through a second purge step with an inert gas and/or the vacuum.

The compositional and optical properties of the resulting SiN_(x) (where 0<x<1.33) thin films have been analyzed by in-situ, real-time, spectroscopic ellipsometry and x-ray photoelectron spectroscopy (XPS), and their wet etch rates were determined using a standard IC industry etch solution. Such results are summarized and discussed below.

Accordingly, by employing the process described herein, high-quality silicon nitride (SiN_(x)) thin films may be grown by remote-plasma pulsed processes from the source precursor 1,3,5-tri(isopropyl)cyclotrisilazane (TICZ, C₉H₂₇N₃Si₃) and remote ammonia (NH₃) soft plasma on substrates such as silicon oxide (SiO₂) within an optimized substrate temperature window ranging from about 200° C. to 350° C. Briefly, the process consists of four-steps: TICZ pulse with no plasma, optional N₂ purge, NH₃ plasma pulse, and N₂ purge. As described below, as-deposited SiN_(x) films prepared from the process described herein were analyzed by spectroscopic ellipsometry and x-ray photoelectron spectroscopy (XPS). Wet etch rates (WER) were determined using a standard solution consisting of 0.5% hydrofluoric acid (HF) in deionized water. XPS analysis yielded a Si:N ratio of ˜1:1 within the entire substrate temperature range and validated the formation of the SiN phase. In situ, real-time ellipsometry measurements confirmed that SiN_(x) growth exhibited a non-self-limiting pulsed behavior. They also yielded an as-grown SiN_(x) average refractive index ˜1.8 for the films grown at substrate temperature above 200° C.

Key findings from the development and optimization of a low-temperature process for SiN_(x) films using the reaction of the source precursor TICZ with NH₃ plasma are as follows. TICZ was selected because it contains three C atoms on each N in the form of propyl groups, which are easily eliminated at moderate temperatures in the form of the gaseous byproduct propylene. TICZ is also generated in high yield and purity from readily available starting materials, as described below, thus demonstrating its suitability for high volume manufacturing. This research led to the identification of an optimized substrate temperature window ranging from 200 to 350° C. for the formation of high-quality Si_(1.0):N_(1.0) films. Wet etch studies in a standard IC industry solution consisting of 0.5% HF in deionized H₂O produced viable etch rates that are competitive with those reported in the literature. Ellipsometry analyses of film nucleation and growth characteristics showed that film formation occurs instantaneously in the first deposition cycle without the existence of an incubation period, in contrast to a number of prior reports in the literature for ALD and CVD SiN_(x), thus eliminating the need for substrate surface pre-treatments that result in additional complexity and added cost of ownership. These results demonstrate that SiN_(x) using TICZ as a silicon source precursor is a viable option for incorporation in emerging heterodevice structures manufacturing process flows.

In another embodiment, the disclosure relates to a process for forming SiC_(x)N_(y) (0.40<x<1.67 and 0.67<y<0.86) thin films using an N-alkyl substituted perhydridocyclotrisilazane precursor and a nitrogen- or caron-containing soft plasma co-reactant at low temperature (substrate temperatures of room temperature to about 200° C.), and, in preferred embodiments, employing TICZ and remote ammonia (NH₃) soft plasma co-reactants. This exemplary process for depositing silicon carbonitride thin films onto a substrate in a reaction zone of a deposition chamber comprises, in a single cycle: heating a substrate to a temperature of room temperature to about 200° C.; maintaining the substrate at room temperature to about 200° C.; providing 1,3,5-tri(isopropyl)cyclotrisilazane in the vapor phase with a carrier gas and/or under vacuum to the reaction zone containing the substrate; forming a monolayer of the 1,3,5-tri(isopropyl)cyclotrisilazane by adsorption to the substrate surface; and exposing the adsorbed monolayer on the substrate in the reaction zone to a remote or direct soft plasma of a nitrogen- or carbon-containing reactant; wherein the adsorbed 1,3,5-tri(isopropyl)cyclotrisilazane monolayer reacts with the soft plasma and undergoes conversion to a discrete atomic or molecular layer of a silicon carbonitride thin film via dissociation and/or decomposition due to or enabled by a substrate surface-induced process; and wherein byproducts of the conversion are removed from the reaction zone via a purge step with an inert gas and/or the vacuum. The cycle is then repeated as many times as desired to form a SiC_(x)N_(y) thin film of a desired or predetermined thickness. The nitrogen-containing chemical species or co-reactant may be, for example and without limitation, NH₃, N₂, a mixture of N₂ and H₂, methylamine and/or hydrazine; NH₃ is presently preferred. The carbon-containing chemical species or co-reactant may be acetylene, for example.

It may be understood that the ranges of substrate temperatures are inclusive of all temperatures within the range, so that temperatures of room temperature to about 200° C. include temperatures such as about 20° C., about 25° C., about 30° C., about 45° C., about 50° C., about 60° C., about 70° C., about 80° C., about 90° C., about 100° C., about 110° C., about 120° C., about 130° C., about 140° C., about 150° C., about 160° C., about 170° C., about 180° C., about 190° C., and about 200° C., and all temperatures in between.

In some embodiments, after forming the monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface, unreacted N-alkyl substituted perhydridocyclotrisilazane and byproducts thereof are removed from the reaction zone through a second purge step with an inert gas and/or the vacuum.

Accordingly, by employing the process described herein, high quality SiC_(x)N_(y) thin films may be grown from 1,3,5-tri(isopropyl)cyclotrisilazane and soft remote ammonia (NH₃) plasma co-reactants. Briefly, the process involves four steps: thermal adsorption of TICZ to the substrate at low temperature (TICZ pulse with no plasma), optional nitrogen (N₂) purge, soft NH₃ remote plasma step, and N₂ purge. These steps are repeated until the desired film thickness is reached. The ratio of C to N in the films may be modulated by controlling the substrate temperature in the range of room temperature to about 200° C., preferably about 30° C. to about 200° C. In-situ analysis of the deposition process has been carried-out using spectroscopic ellipsometry, and the films were analyzed by x-ray photoelectron spectroscopy (XPS). The findings of this study indicate that the combination of reduced substrate thermal budget and soft remote plasma provides an optimum low energy environment for the controlled deposition of SiC_(x)N_(y) protective coatings on thermally fragile, chemically sensitive substrates, including plastics and polymers.

As described below, it has been found that low (near room temperature) SiC_(x)N_(y) deposition using TICZ and soft remote ammonia (NH₃) plasma as co-reactants yielded SiC_(x)N_(y) thin films with 0.40<x<1.67 and 0.67<y<0.86 in the substrate temperature range of 30 to 150° C. XPS analysis indicated that the SiC_(x)N_(y) films consisted predominantly of a temperature-independent matrix of simple cross-linked Si—C and Si—N bonds. In situ, real-time, angle-resolved ellipsometry showed that all films were grown in a plasma pulse regime, with film nucleation and growth occurring instantaneously without an incubation period similar to that reported in the literature for ALD and P-CVD work. This feature makes this SiC_(x)N_(y) process attractive from a manufacturing perspective due to the elimination of ex-situ or in-situ pre-deposition substrate surface treatments, leading to an increase in process efficiency and a reduction in both process steps and cost of ownership. These findings therefore demonstrate that applying a soft remote plasma in concert with a reduced substrate thermal budget where TICZ and NH₃ co-reactants are directed to react only on the substrate surface constitutes a promising approach for growing of SiC_(x)N_(y) protective coatings within a low energy environment for potential applications that require thermally fragile, chemically sensitive substrates, including plastics and polymers.

In a further embodiment, the disclosure relates to a method for deposition of a silicon oxide thin film onto a substrate in a reaction zone of a deposition chamber. The method comprises, in a single cycle: heating a substrate to a temperature of about 200° C. to about 650° C., preferably about 200° C. to about 350° C.; maintaining the substrate at about 200° C. to about 650° C., preferably about 200° C. to about 350° C.; providing a precursor comprising a N-alkyl substituted perhydridocyclotrisilazane in the vapor phase with a carrier gas and/or under vacuum to the reaction zone containing the substrate; forming a monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface; and exposing the adsorbed monolayer on the substrate in the reaction zone to a remote or direct soft plasma of an oxygen-containing reactant; wherein the adsorbed N-alkyl substituted perhydridocyclotrisilazane monolayer reacts with the soft plasma and undergoes conversion to a discrete atomic or molecular layer of a silicon oxide thin film via dissociation and/or decomposition due to or enabled by a substrate surface-induced process; and wherein byproducts of the conversion are removed from the reaction zone by an inert gas through a purge step and/or the vacuum. The cycle is then repeated as many times as desired to form a silicon oxide thin film of a desired or predetermined thickness. The oxygen-containing chemical species or co-reactant may be, for example and without limitation, ozone, O₂, and water. The preferred N-alkyl substituted perhydridocyclotrisilazane is TICZ.

It may be understood that the ranges of substrate temperatures are inclusive of all temperatures within the range, so that temperatures of about 200° C. to about 650° C. include temperatures such as about 225° C., about 250° C., about 275° C., about 300° C., about 325° C., about 300° C., about 325° C., about 350° C., about 375° C., about 400° C., about 425° C., about 450° C., about 475° C., about 500° C., about 525° C., about 550° C., about 575° C., about 600° C., about 625° C., and about 650° C., and all temperatures in between.

In some embodiments, after forming the monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface, unreacted N-alkyl substituted perhydridocyclotrisilazane and byproducts thereof are removed from the reaction zone through a second purge step with an inert gas and/or the vacuum.

In a further embodiment, the disclosure provides a method for deposition of a silicon thin film onto a substrate in a reaction zone of a deposition chamber, the method comprising, in a single cycle: heating a substrate to a temperature of about 200° C. to about 650° C., preferably about 200° C. to about 350° C.; maintaining the substrate at about 200° C. to about 650° C., preferably about 200° C. to about 350° C.; providing a precursor comprising a N-alkyl substituted perhydridocyclotrisilazane in the vapor phase with a carrier gas and/or under vacuum to the reaction zone containing the substrate; forming a monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface; and exposing the adsorbed monolayer on the substrate in the reaction zone to a remote or direct soft plasma of a hydrogen-containing reactant; wherein the adsorbed N-alkyl substituted perhydridocyclotrisilazane monolayer reacts with the soft plasma and undergoes conversion to a discrete atomic or molecular layer of a silicon thin film via dissociation and/or decomposition due to or enabled by a substrate surface-induced process; and wherein byproducts of the conversion are removed from the reaction zone by an inert gas through a purge step and/or the vacuum. The cycle is then repeated as many times as desired to form a silicon oxide thin film of a desired or predetermined thickness. The hydrogen-containing chemical species or co-reactant may be, for example and without limitation, H₂. The preferred N-alkyl substituted perhydridocyclotrisilazane is TICZ.

It may be understood that the ranges of substrate temperatures are inclusive of all temperatures within the range, so that temperatures of about 200° C. to about 650° C. include temperatures such as about 225° C., about 250° C., about 275° C., about 300° C., about 325° C., about 300° C., about 325° C., about 350° C., about 375° C., about 400° C., about 425° C., about 450° C., about 475° C., about 500° C., about 525° C., about 550° C., about 575° C., about 600° C., about 625° C., and about 650° C., and all temperatures in between.

In some embodiments, after forming the monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface, unreacted N-alkyl substituted perhydridocyclotrisilazane and byproducts thereof are removed from the reaction zone through a second purge step with an inert gas and/or the vacuum.

The invention will now be described in conjunction with the following, non-limiting examples.

Example 1: Formation of SiN Thin Film Synthesis of Precursor

Under an argon atmosphere, a 5-liter 4-necked flask equipped with a cooling bath, overhead stirrer, pot thermometer, sub-surface dip-tube, and dry-ice condenser was charged with 909 grams of methyl t-butyl ether. The mixture was cooled to −40° C., and then 303.0 grams (3 moles) of dichlorosilane were slowly added to the pot. 364.7 grams (6.0 moles) of isopropylamine were then added via dip-tube at temperatures in the range of −30 to −20° C. over a period of 2.5 hours. After the addition was completed, the reaction mixture was slowly warmed up to 25° C. and stirred at this temperature for 8 to 14 hours. This step was followed by the addition of 177.4 g (3 moles) of isopropylamine at temperatures in the range of 0 to 40° C., and the subsequent addition of another 227.3 grams of methyl t-butyl ether. The mixture was stirred for 6 to 16 hours and monitored by gas chromatography (GC). The reaction solution was then filtered and solvents were removed from the filtrates under reduced pressure below 50° C. The filtering process was repeated, with fractional distillation of the clear filtrates yielding 64.5 g (24.66) of TiCZ.

TICZ vapor pressure was determined by a combination of distillation temperature, pressure readings (<10 torr), and pressure-cell DSC measurements (>10 torr). The latter employed a TA Instruments Pressure DSC 25P instrument utilizing Tzero Hermetic Pinhole (75 μm) Lids, 2-5 mg sample size, and a 15° C./min ramp rate. FIG. 1 provides actual vapor pressure data from distillation and DSC measurements, as well as Antoine Equation's fit [Log(P)=A−B/(C+T)] over the range of 0.14 to 760 torr.

Processing Conditions for SiN Thin Film Deposition

A Picosun R-200 R&D system equipped with a sample load-lock to maintain the cleanliness and vacuum integrity of the reaction chamber and a remote inductively-coupled plasma (ICP) power source was employed in process development and optimization. All depositions were performed on substrates consisting of 1000 nm-thick silicon dioxide thermally grown on n-doped Si wafers, acquired from Addison Engineering. The samples were loaded as-received and were subjected to an in-situ NH₃ plasma clean at a plasma frequency of 13.56 MHz and a plasma power of 2000 W for five minutes before each deposition run.

The TICZ precursor was loaded in a specialized bubbler which was connected to the Picosun precursor manifold system and heated to 50° C. All delivery lines were also heated to 90° C. to inhibit premature precursor condensation prior to entering the reaction chamber. N₂ gas was used as carrier gas and set at 100 sccm.

Process development and optimization for SiN_(x) from the reaction of TICZ and NH₃ plasma was carried out in two phases. In a first “proof-of-concept” phase, a systematic set of screening experiments were conducted to identify optimum values for the duration of the TICZ pulse, purge step, and NH₃ plasma pulse, as well as N₂ purge gas flow rate, NH₃ remote plasma flow rate, and plasma power. In a second “process optimization” phase, the key experimental parameters were set as shown in FIG. 2 and the substrate temperature was varied from 50° C. to 350° C. in 50° C. intervals. Precursor exposure and plasma pulse durations and purge times were identical for substrate temperatures of 50, 150, 200, 250, 300, and 350° C., except no precursor purge time was applied in the 350° C. run. NH₃ remote plasma frequency, flow rate, and power were set at 13.56 MHz, 40 sccm, and 2000 W, respectively. The samples were subsequently transferred to the load lock system and allowed to cool to room temperature in a N₂ atmosphere prior to removal from the Picosun system.

For XPS analysis, the SiN_(x) samples were capped with an approximately 10-15 nm-thick zinc oxide (ZnO_(x)) layer to prevent surface contamination during transport and handling. The ALD ZnO, process employed 100 cycles of the reaction of diethyl-zinc (DEZ) as the Zn source and water as the oxygen source. ZnO_(x) was grown in-situ immediately following and at the same temperature as the SiN_(x) deposition, except in the case of the 50° C. sample, in which the temperature was increased to 150° C. for the ZnO_(x) deposition. The process consisted of a four-steps: 0.1 sec DEZ pulse, 5 secs N₂ purge, 0.1 sec water vapor pulse, 5 secs N₂ purge.

Analytical Techniques

In-situ, real-time, angle-resolved ellipsometry was performed using a Woollam iSE ellipsometer at wavelengths ranging from 400 to 1000 nm. The ellipsometer system was mounted directly on the P-CVD (pulsed-CVD) reaction chamber, with the incident light beam being directed onto the substrate through a quartz glass window at an incident angle of 60.8°, and the reflected light beam being captured by a detector. The resulting data was analyzed using CompleteEASE software. The substrate was modelled as a ˜1000 nm-thick thermal SiO₂ layer on Si. The thickness of the SiO₂ layer was measured in-situ prior to every P-CVD run.

XPS was carried out at Eurofins EAG Materials Science, LLC on a PHI Quantum 2000 system. X-rays were generated from a monochromated Alk_(α) source at 1486.6 eV and directed at the sample at a ±230 acceptance angle and 45° take-off angle. In-depth compositional analysis was performed with an Ar⁺ ion gun at 2 keV, 4 mm×2 mm raster, and 3.8 nm/min sputter rate. No deconvolution was applied to the data since the Si, N, C, and O peaks were well separated from each other. All data processing (integration) was performed using CasaXPS software from Casa Software Ltd. Montage plots were generated using MultiPak software, produced by Ulvac-phi, Inc. Depth profile plots were produced using Microcal Origin, manufactured by Microcal Software, Inc. High-resolution XPS peaks assignments were performed following the calibration procedure described in ISO 15472:2010 “Surface chemical analysis—X-ray photoelectron spectrometers—Calibration of energy scales.

Wet etch studies were conducted using an IC industry standard solution consisting of 0.5% hydrofluoric acid (HF) in deionized water at room temperature.

Precursor Analysis

One additional advantage of 1,3,5-tri(isopropyl)cyclotrisilazane (TICZ, C₉H₂₇N₃Si₁₃) is that it was generated at high yield and purity from readily available starting materials, as described above. This ensures its suitability for high volume manufacturing. Pertinent properties of TICZ are displayed in Table I and its vapor pressure versus temperature parameters are shown in FIG. 1. It should be noted that the precursor synthesis recipe described earlier can also produce other analogs, such as 1,3,5-tri(ethyl)cyclotrisilazane and 1,3,5-tri(t-butyl)cyclotrisilazane, which have different volatility and deposition characteristics.

TABLE I Chemical Structure and Properties of TICZ Property Value Comments Chemical Structure

Boiling Point (° C.) 67-68 @ 1.8 torr Density (g/cm³) 0.919 @ 20° C. Vapor Pressure (torr) ~1 torr @ 70° C. See FIG. 1 FTIR vS-H:2113.6 (vs) ¹HNMR (CDCl₃): 1.29 (d, 18H) 3.38 (m, 3H)  4.80 (s, 6H) 

Ellipsometry Analysis

FIG. 3 depicts in-situ, real-time ellipsometry profiles of film thickness versus duration of deposition for films grown at 200° C. substrate temperature for TICZ pulse times of 0.4 sec, 1.0 sec, 2.0 secs, 3.0 secs, and 5.0 secs. As shown in the profiles, film thickness continues to increase with precursor pulse time and does not saturate, regardless of precursor pulse time. This behavior shows that the TICZ adsorption step is not self-limiting and supports the assertion that the growth of SiN_(x) films does not occur through an ALD process. The same film thickness dependence on pulse time was observed within the entire substrate temperature range investigated, from 50° C. to 350° C., indicating that film formation does not occur through an ALD growth mode within all the process windows investigated.

Similarly, FIGS. 4 and 5 display plots of in-situ, real-time, ellipsometry measurements of film thickness versus deposition time for substrate temperatures of 150, 175, 200, 225, 300, and 350° C. As expected, FIG. 4 shows that film thickness increases with longer deposition time. However, a gradual decrease in the slope of each film thickness curve is also observed with higher substrate temperature. This decrease is indicative of a reduction in growth rate per cycle (GPC) with the rise in substrate temperature. It is suggested that the decline in GPC is attributed to a reduction in precursor partial vapor pressure in the reaction zone in proximity of the substrate. This decrease is believed to be possibly due to the geometry of the deposition chamber, which induces additional heating at the point of entry of the precursor into the reactor with increased substrate temperature, leading to some precursor decomposition prior to reaching the reaction zone. Alternatively, the decrease could be caused by a higher frequency of recombination of precursor species and associated ligands with the rise in thermal budget, and their subsequent desorption from the substrate surface, thus restricting the TICZ and NH₃ reaction rate.

Furthermore, FIG. 5 shows that film formation occurs instantaneously in the first deposition cycle without the manifestation of an incubation period or delay in film nucleation and growth, in contrast to a number of prior reports in the literature for SiN_(x) produced from ALD and CVD. This feature is important as it negates the requirement for substrate surface pre-treatments, thus eliminating added complexity and cost in the incorporation of SiN_(x) deposition in heterodevice structures manufacturing process flows. In addition, Table II presents ellipsometry-derived values for film thickness, growth rate per cycle (GPC), and index of refraction for as-deposited SiN_(x) films as a function of substrate temperature.

TABLE II Selected Properties of SiN_(x), as Determined by Ellipsometry, XPS, and Wet etching Substrate Film Growth Optimum Temperature Thickness Rate Etch Rate Refractive (° C.) (nm) (nm/cycle) (nm/min) index 50 2947.6 0.590 2309.7 1.491 150 289.3 0.231 732 1.513 200 87.3 0.029 98.5 1.800 250 101.9 0.025 25.2 1.813 300 104.1 0.021 12.2 1.807 350 57.5 0.019 2.4 1.815

XPS Analysis

Selected film thicknesses were also confirmed by XPS depth profile analyses. Zn, Si, N, C, and O concentrations versus penetration depth in SiN_(x) films were assessed by XPS depth profile analyses, as shown in FIGS. 6 and 7 for as-deposited SiN_(x) films grown at substrate temperatures of 200° C. and 300° C., respectively.

The measurements yielded decreasing C concentrations of ˜42 at % and ˜15 at % for films grown at 50° C. and 150° C. substrate temperatures, respectively. The value declined to below the detection limits of XPS above 200° C. substrate temperature, as can be seen in FIG. 6. The XPS results therefore indicate that 200° C. provides the minimum thermal budget required for efficient reaction of TICZ and NH₃, leading to complete precursor dissociation, and removal of reaction byproducts from the deposition zone. Similarly, O concentrations of ˜11 at % and ˜6 at % were recorded for films grown at 50° C. and 150° C. substrate temperatures, respectively. The value declined to ˜5 at % above 200° C. substrate temperature, as shown in FIG. 6. Oxygen inclusion is attributed to O diffusion during the in-situ P-CVD zinc oxide (ZNO_(x)) capping layer deposition step.

Table III provides representative SiN_(x) atomic concentrations within the bulk of films grown at 200° C., 250° C., and 300° C. at a depth of ˜25 nm. The data in Table III, as well as FIGS. 6 and 7, demonstrate that samples deposited above 200° C. consisted of Si:N ratio of ˜1:1.

High-resolution XPS spectra for Si2p, N1s, C1s, and O1s binding energies versus penetration depth are displayed in FIGS. 8 and 9 for SiN_(x) films deposited at 200° C. and 300° C., respectively. The data demonstrate that both sets of films consisted of a SiN phase with a low concentration of O and practically no C inclusion. It should be noted that the N1s spectra contained a main peak attributed to N(—Si)₃, which is due to Si—N bonding, nitride and a minor peak attributed to O—N(—Si)₂, which is associated with silicon oxynitride (Si_(x)N_(y)O_(z)).

TABLE III Representative SiN_(x) Atomic concentrations (in at %) Within the Bulk of Films Grown at 200, 250, and 300° C. Depth Substrate in Temperature Sample (° C.) (nm) C N O Si 200 ~25 ~0.7 ~47.5 ~3.2 ~48.5 250 ~25 ~0.2 ~46.9 ~5.4 ~47.5 300 ~25 ~0.0 ~47.2 ~5.6 ~47.3

Wet Etch Rate

Wet etch studies were conducted using an IC industry standard solution consisting of 0.5% hydrofluoric acid (HF) in deionized water. The results are summarized in Table II. The wet etch rates observed for films deposited at 300° C. are competitive with those reported in prior art including, for example, for LPCVD films grown at 770° C. and PE-ALD films deposited at 250° C. etched in a milder etch solution consisting of 1:300 HF:H₂O solution; and PE-ALD films grown between 270 and 350° C. and treated in a more diluted wet etch solution consisting of 1:500 HF:H₂O.

Example 2: Formation of SiCxNy Thin Film Experimental Deposition Conditions

All experiments were performed in the same Picosun R-200 R&D reactor described earlier. SiC_(x)N_(y) film growth experiments were conducted in two stages. In a first screening stage, systematic scoping experiments were performed to establish optimized run parameters, including process working pressure, remote NH₃ plasma power, and precursor, NH₃, and N₂ flow rates, as well as the length of the pre-deposition plasma treatment step, and the duration of the TICZ, N₂ purge, and remote NH₃ plasma pulse steps. Once this stage was completed and appropriate experimental parameter sets were identified, a second process optimization stage was implemented to determine SiC_(x)N_(y) compositional, physical, and chemical properties as a function of substrate temperature in the range of 30° C. to 200° C. For this stage, the NH₃ flow rate was kept constant at 40 sccm, while remote plasma power and frequency were set at 2000 W and 13.56 MHz, respectively. Table IV summarizes the key run parameters.

TABLE IV Key Processing Parameters for Soft Remote Plasma SiC_(x)N_(y) Deposition Processing Parameter Value Description Precursor TICZ (C₉H₂₇N₃Si₃) @ 50° C.

Substrate 30-200° C. 30, 50, 60, 90, 120, 150, Temperature TICZ Pulse 0.4 s  170, 200 Duration (N₂ carrier gas @ 100 sccm) N₂ Purge 2.0 s @ 100 sccm NH₃ Remote 10.0 s  @ 40 sccm, 2000 W Plasma Pulse N₂ Purge 3.0 s  @ 100 sccm ZnO_(x) Capping Standard ALD 0.1 s DEZ pulse, 5 s N₂ Layer Process Diethyl purge, Zinc (DEZ) 0.1 s H₂O pulse, 5 s N₂ and H₂O purge. (10-15 nm thick)

The SiC_(x)N_(y) growth runs were followed in-situ with the deposition of an approximately 10 to 15 nm-thick zinc oxide (ZnO_(x)) capping layer to prevent SiC_(x)N_(y) contamination upon exposure to air and during subsequent transport and handling. For the ZnO_(x) step, a standard ALD process was employed. The substrate temperature was maintained at the same value as the SiC_(x)N_(y) deposition step, except in the case of the 50° C. SiC_(x)N_(y) film, for which the temperature was increased to 150° C. for the ZnO_(x) growth step. The ALD ZnO_(x) process employed the reaction of diethyl zinc (DEZ) and water (H₂O) as the Zn and O sources, respectively: it involved a 0.1 s DEZ pulse and 0.1 s H₂O vapor pulse, separated by 5 s N₂ purge each.

At the conclusion of each deposition run, the samples were transferred back into the load lock system and kept under a N₂ atmosphere until they cooled down to room temperature prior to removal from the Picosun system.

Analytical Techniques

To study the composition and chemical bonding characteristics of the SiC_(x)N_(y) films, the same analytical techniques were employed as previously described.

XPS Analysis

Table V presents representative atomic concentration percentages of Si, C, N, and O in films deposited at 50, 150, and 200° C. The values were determined by quantitative XPS analysis, as shown in FIGS. 10 and 11 for SiC_(x)N_(y) samples deposited at 50 and 150° C., respectively.

TABLE V Representative Atomic concentrations (in at % rounded to the nearest whole number) Within the Bulk of SiC_(x)N_(y) Films Grown at Various Substrate Temperatures Substrate Temperature Depth in (° C.) Sample (nm) Si C N O 50 ~25 ~27 ~45 ~18 ~10 150 ~25 ~43 ~17 ~37 ~3 200 ~25 ~48 ~0 ~48 ~5

Oxygen content in the films was ˜10 at % at 50° C. and decreased to 3-5 at % at higher temperatures. The presence of this small concentration of O could be due to H₂O reaction with SiC_(x)N_(y) during the subsequent in-situ ALD ZnO_(x) capping layer step. It could also result from impurities in NH₃ or N₂ and/or the well-known issue of plasma etching of the Al₂O₃ dielectric liners that are employed in ICP plasma sources. A gradual decrease in C concentration was also observed at higher substrate temperature, while the N content exhibited a steady increase, as seen in Table V and in FIGS. 10 and 11.

These trends are consistent with the observation that the combination of reduced substrate thermal budget and soft remote plasma provides an optimum low energy environment for the alkyl groups to undergo a gradual and controlled dissociation reaction from the parent molecule; a rise in substrate temperature provides increased thermal activation energy for a higher degree of bond dissociation as well as Si, C, and N bond re-distribution within the SiC_(x)N_(y) film.

High-resolution XPS core level spectra for Si 2p, N 1s, C 1s, and O 1s binding energies versus penetration depth in SiC_(x)N_(y) were also compiled for the samples deposited at 50 and 150° C., respectively, as shown in FIGS. 12 and 13. Based on the XPS analysis, the location of the Si, N, C, and O core levels peaks appears to be independent of film composition and process thermal budget. More specifically, within the 30 to 150° C. substrate temperature window investigated, the C 1s peak location at ˜283.3 eV is attributed to C—Si bonds, while the N 1s peak position at ˜397.3 eV is due to N—Si bonds, regardless of the substrate temperature used. Concurrently, the Si 2p peak is composed of contributions from Si—C bonds at ˜100.4 eV and Si—N bonds at ˜101.7 eV, with perhaps a negligible contribution from Si—O bonds at 103 eV.

The high-resolution XPS analysis seems to indicate that the SiC_(x)N_(y) films consist predominantly of a matrix of simple cross-linked Si—C and Si—N bonds for substrate temperatures ≤150° C. No C is observed in the films within XPS detection limits at 200° C., with the Si 2p and N 1s peaks corresponding to a SiN phase.

This results are radically different from previously described films. In the latter, an evolution was reported that the C1s peak in SiC_(x)N_(y) underwent a transition from C—C to C—Si to C—N type bonds as function of increased substrate temperature, while the N 1s peak exhibited a transition from N—C to predominantly N—Si bonding with some contribution from N—C type bonds. Concurrently, the Si 2p were reported to evolve from Si—N, Si—O, and Si—C type bonding to mainly Si—Si bonds, along with Si—N and Si—C bonds. These results were attributed to the presence of various temperature-dependent complex bonding configurations in previously described SiC_(x)N_(y) films. Unlike previously reported films, the simple Si—C and Si—N bonds in the inventive SiC_(x)N_(y) films, with no changes in the bonding configuration or chemical structure as function of temperature, provide a stable and consistent SiC_(x)N_(y) matrix for applications that require thermally fragile, chemically sensitive substrates, including plastics and polymers.

The results described and demonstrated herein are different from prior findings in the literature, e.g., atmospheric pressure plasma CVD (AP-PECVD) from triethylsilane (HSiEt₃, TES) and N₂ as Si, C, and N sources. In the latter, it was reported that the C 1s peak indicated an evolution from C—C to C—Si to C—N type bonds, while the N 1s peak exhibited a transition from N—C to predominantly N—Si bonding with some contribution from N—C type bonds. Concurrently, the Si 2p were reported to evolve from Si—N, Si—O, and Si—C type bonding to mainly Si—Si bonds, along with Si—N and Si—C bonds. These results were attributed to the presence of various temperature-dependent complex bonding configurations in a-SiCN films, as described in a number of other reports by various researchers.

XPS analysis therefore supports the assertion that applying a soft remote plasma in concert with a reduced substrate thermal budget in a pulsed mode where the N-alkyl substituted perhydridocyclotrisilazane precursor and NH₃ co-reactant are directed to react only on the substrate surface does yield: (i) a SiC_(x)N_(y) matrix with a temperature-independent bonding configuration of simple cross-linked Si—C and Si—N bonds: and (ii) a gradual and controlled decrease in C content with increasing substrate temperature.

Ellipsometry Analysis

In-situ, real-time ellipsometry studies were implemented for the adsorption and reaction pathways of the TICZ source precursor and NH₃ remote plasma, as well as the resulting SiC_(x)N_(y) film nucleation and growth profiles, in order to determine the nature and characteristics of the pulsed deposition process. To this end, FIG. 14 displays SiC_(x)N_(y) film thickness as a function of deposition time for TICZ pulse times of 0.1, 0.2, 0.4, and 0.8 s. Substrate temperature was maintained at 150° C. in all runs. The data indicate that film thickness exhibits a steady rise with higher TICZ pulse durations and does not reach a plateau at which it ceases to increase, as would have been expected in an ALD process. It should be noted that this trend is observed across the entire substrate temperature window investigated, indicating that the pulsed deposition of SiC_(x)N_(y) does occur in a P-CVD rather than an ALD regime. One advantage of the plasma pulsed mode is the potential partial decomposition of the parent TICZ precursor upon adsorption to the substrate surface and prior to reaction with NH₃, a feature that is conducive to film deposition in a lower thermal budget window.

Similarly, FIG. 15 provides in-situ, real-time, angle-resolved ellipsometry measurements of film thickness versus deposition time for substrate temperatures of 30, 60, 90, 120, 150, and 170° C. The plots show that film nucleation and growth occur instantaneously, as indicated by the immediate rise in film thickness within the first deposition cycle. This feature is important, as it demonstrates the absence of an incubation period prior to the onset of SiC_(x)N_(y) film formation, as has been reported in the literature for other ALD and P-CVD work. The absence of such an incubation period makes plasma pulsed SiC_(x)N_(y) more attractive from a manufacturing perspective by eliminating ex-situ or in-situ pre-deposition substrate surface treatments, thereby resulting in a reduction in the number of process steps required to grow SiC_(x)N_(y) thin films.

Additionally, FIG. 15 shows a gradual decrease in the slope of the film thickness curves, and thus the SiC_(x)N_(y) growth rate per cycle, with increasing substrate temperature. The reduction in GPC at higher substrate temperatures could potentially be caused by: (i) a decrease in TICZ partial vapor pressure in proximity to the substrate due to the geometry of the reactor, which induces a gradual rise in precursor decomposition at its point of entry into the chamber and prior to reaching the substrate, and/or (ii) a higher rate of desorption of the precursor and associated moieties from the substrate surface prior to the NH₃ co-reactant step due to the rise in thermal budget. Finally, ex-situ ellipsometry measurements yielded refractive indices of ˜1.49, ˜1.51, and ˜1.80 for the films deposited at 50, 150, and 200° C., respectively.

Wet Etch Rates

Wet etch rate (WER) studies produced values of 2310, 732, and 99 nm/min for the films grown at 50, 150, and 200° C., respectively.

It will be appreciated by those skilled in the art that changes could be made to the embodiments described above without departing from the broad inventive concept thereof. It is understood, therefore, that this invention is not limited to the particular embodiments disclosed, but it is intended to cover modifications within the spirit and scope of the present invention as defined by the appended claims. 

We claim:
 1. A method for deposition of a silicon nitride thin film onto a substrate in a reaction zone of a deposition chamber, the method comprising, in a single cycle: heating a substrate to a temperature of about 200° C. to about 650° C.; maintaining the substrate at about 200° C. to about 650° C.; providing a precursor comprising a N-alkyl substituted perhydridocyclotrisilazane in the vapor phase with a carrier gas and/or under vacuum to the reaction zone containing the substrate; forming a monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface; and exposing the adsorbed monolayer on the substrate in the reaction zone to a remote or direct soft plasma of a nitrogen-containing reactant; wherein the adsorbed N-alkyl substituted perhydridocyclotrisilazane monolayer reacts with the soft plasma and undergoes conversion to a discrete atomic or molecular layer of a silicon nitride thin film via dissociation and/or decomposition due to or enabled by a substrate surface-induced process; and wherein byproducts of the conversion are removed from the reaction zone via a purge step with an inert gas and/or the vacuum.
 2. The method according to claim 1, further comprising after forming the monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface, removing unreacted N-alkyl substituted perhydridocyclotrisilazane and byproducts thereof from the reaction zone through a second purge step with an inert gas and/or the vacuum.
 3. The method according to claim 1, wherein the substrate temperature is about 200° C. to about 350° C.
 4. The method according to claim 1, wherein the N-alkyl substituted perhydridocyclotrisilazane is 1,3,5-tri(isopropyl)cyclotrisilazane.
 5. The method according to claim 1, wherein the nitrogen-containing reactant comprises NH₃, N₂, a mixture of N₂ and H₂, methylamine, and/or hydrazine.
 6. The method according to claim 1, wherein the single cycle is repeated until a thin film of a predetermined thickness is achieved.
 7. The method according to claim 1, wherein the substrate surface-induced process is energy transfer, remote plasma application, direct plasma application, oxidation, and/or reduction.
 8. A method for deposition of a silicon oxide thin film onto a substrate in a reaction zone of a deposition chamber, the method comprising, in a single cycle: heating a substrate to a temperature of about 200° C. to about 650° C.; maintaining the substrate at about 200° C. to about 650° C.; providing a precursor comprising a N-alkyl substituted perhydridocyclotrisilazane in the vapor phase with a carrier gas and/or under vacuum to the reaction zone containing the substrate; forming a monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface; and exposing the adsorbed monolayer on the substrate in the reaction zone to a remote or direct soft plasma of an oxygen-containing reactant; wherein the adsorbed N-alkyl substituted perhydridocyclotrisilazane monolayer reacts with the soft plasma and undergoes conversion to a discrete atomic or molecular layer of a silicon oxide thin film via dissociation and/or decomposition due to or enabled by a substrate surface-induced process; and wherein byproducts of the conversion are removed from the reaction zone by an inert gas through a purge step and/or the vacuum.
 9. The method according to claim 8, further comprising after forming the monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface, removing unreacted N-alkyl substituted perhydridocyclotrisilazane and byproducts thereof from the reaction zone through a second purge step with an inert gas and/or the vacuum.
 10. The method according to claim 8, wherein the substrate temperature is about 200° C. to about 350° C.
 11. The method according to claim 8, wherein the N-alkyl substituted perhydridocyclotrisilazane is 1,3,5-tri(isopropyl)cyclotrisilazane.
 12. The method according to claim 8, wherein the oxygen-containing reactant is ozone, water, and/or O₂ plasma.
 13. The method according to claim 8, wherein the single cycle is repeated until a thin film of a predetermined thickness is achieved.
 14. The method according to claim 8, wherein the substrate surface-induced process is energy transfer, remote plasma application, direct plasma application, oxidation, and/or reduction.
 15. A method for deposition of a silicon carbonitride thin film onto a substrate in a reaction zone of a deposition chamber, the method comprising, in a single cycle: heating a substrate to a temperature of room temperature to about 200° C.; maintaining the substrate at room temperature to about 200° C.; providing a precursor comprising a N-alkyl substituted perhydridocyclotrisilazane in the vapor phase with a carrier gas and/or under vacuum to the reaction zone containing the substrate; forming a monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface; and exposing the adsorbed monolayer on the substrate in the reaction zone to a remote or direct soft plasma of a nitrogen-containing reactant; wherein the adsorbed N-alkyl substituted perhydridocyclotrisilazane monolayer reacts with the soft plasma and undergoes conversion to a discrete atomic or molecular layer of a silicon carbonitride thin film via dissociation and/or decomposition due to or enabled by a substrate surface-induced process; and wherein byproducts of the conversion are removed from the reaction zone by an inert gas through a purge step and/or the vacuum.
 16. The method according to claim 15, further comprising after forming the monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface, removing unreacted N-alkyl substituted perhydridocyclotrisilazane and byproducts thereof from the reaction zone through a second purge step with an inert gas and/or the vacuum.
 17. The method according to claim 15, wherein the N-alkyl substituted perhydridocyclotrisilazane is 1,3,5-tri(isopropyl)cyclotrisilazane.
 18. The method according to claim 15, wherein the nitrogen-containing reactant comprises NH₃, N₂, a mixture of N₂ and H₂, methylamine, and/or hydrazine.
 19. The method according to claim 15, wherein the single cycle is repeated until a thin film of a predetermined thickness is achieved.
 20. The method according to claim 15, wherein the substrate surface-induced process is energy transfer, remote plasma application, direct plasma application, oxidation, and/or reduction.
 21. A method for deposition of a silicon thin film onto a substrate in a reaction zone of a deposition chamber, the method comprising, in a single cycle: heating a substrate to a temperature of about 200° C. to about 650° C.; maintaining the substrate at about 200° C. to about 650° C.; providing a precursor comprising a N-alkyl substituted perhydridocyclotrisilazane in the vapor phase with a carrier gas and/or under vacuum to the reaction zone containing the substrate; forming a monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface; and exposing the adsorbed monolayer on the substrate in the reaction zone to a remote or direct soft plasma of a hydrogen-containing reactant; wherein the adsorbed N-alkyl substituted perhydridocyclotrisilazane monolayer reacts with the soft plasma and undergoes conversion to a discrete atomic or molecular layer of a silicon thin film via dissociation and/or decomposition due to or enabled by a substrate surface-induced process; and wherein byproducts of the conversion are removed from the reaction zone by an inert gas through a purge step and/or the vacuum.
 22. The method according to claim 21, further comprising after forming the monolayer of the N-alkyl substituted perhydridocyclotrisilazane by adsorption to the substrate surface, removing unreacted N-alkyl substituted perhydridocyclotrisilazane and byproducts thereof from the reaction zone through a second purge step with an inert gas and/or the vacuum.
 23. The method according to claim 21, wherein the substrate temperature is about 200° C. to about 350° C.
 24. The method according to claim 21, wherein the N-alkyl substituted perhydridocyclotrisilazane is 1,3,5-tri(isopropyl)cyclotrisilazane.
 25. The method according to claim 21, wherein the single cycle is repeated until a thin film of a predetermined thickness is achieved.
 26. The method according to claim 21, wherein the substrate surface-induced process is energy transfer, remote plasma application, direct plasma application, oxidation, and/or reduction. 